KR100596352B1 - Tires with body ply reinforcement with two strength levels - Google Patents

Abstract

The present invention relates to a tire (P) having a carcass reinforcement (1), the reinforcement (1) is radially covered to the outside by the crown reinforcement (3), the reinforcement (3) cross each other reinforcement The carcass reinforcement 1 at the AB part arranged below the crown reinforcement 3 consists of two acting crown plies 31, 32 of the element and forms an angle in the range of 10 ⁰ and 45 ⁰ with respect to the circumference. Formed of stiffener elements.

Tires, reinforcements, plies, cuts

Description

Tire with body ply reinforcement having two rigidity levels

The present invention relates to a tire having a radial carcass reinforcement covered radially with a crown reinforcement, wherein the crown reinforcement is parallel to each other in each ply and intersects in one ply so as to be 10 ⁰ to 45 ⁰ relative to the circumferential direction. It consists of two or more action plies formed of stiffener elements that form small absolute angles in the range.

In tires corresponding to the present state of the art, carcass stiffeners are formed of one or more stiffener elements which are radial or limiting radial, ie stiffener elements which form an angle of 90 ⁰ ± 10 ⁰ with respect to the circumferential direction. The reinforcement element is a textile cable used in general purpose tires for passenger cars, aircrafts or agricultural machinery with one or more carcass plies, and generally a metallic cable for tires of large road vehicles or civil machines with only one carcass ply. This is used. The stiffener elements extend in succession from one bead wire to another and are secured at each tire bead by rotating around the bead wire.

During the manufacture of a tire, a ply of carcass reinforcement, either metallic or metallic, such as steel or steel, is first placed on a cylindrical drum and then molded and toroidal tire blank before being radially covered with the crown reinforcement. blank). While molding in the mold of the vulcanization press, the toroidal tire blanks thus formed are subjected to further molding processes.

In the case of tires in which the reinforcement element is unextended, i.e., with a metallic carcass reinforcement which hardly extends at a tensile force equal to 10% of the breakdown force, various deformations caused by unvulcanized carcass and tire blanks, in particular the shoulder of the tire ( A phenomenon known as the flow of the intermediate layer of rubber mixture occurs in the shoulder region. This flow phenomenon may change in the circumferential direction and may be an important factor in reducing the durability of the carcass reinforcement of the tire. In the case of a tire having a radial carcass reinforcement consisting of a reinforcement element made of a heat shrinkable fabric or plastic material, vulcanization of the tire results in the flow phenomenon of the same intermediate layer.

An important solution to solve this problem is to significantly increase the thickness of the inner layer, but obviously the same, and the solution is to increase the tire (because the excess thickness generates more heat in the shoulder and increases rolling resistance, etc.) It may not be an optimal solution in terms of the properties or the cost of production.

Patent FR 1 111 805 to the applicant discloses a carcass reinforcement formed of two parts which overlap in the equator plane of the tire. Arranging plies of carcass reinforcement or these plies in this manner has advantages in both the flexibility of the tire and the ease of manufacture of the tire.

Patent FR 1 111 806 discloses the same configuration of two parts of a radial carcass reinforcement to compensate for the shortcomings of a triangular ply radially located above the working crown ply.

This configuration of the carcass ply layer, which is not continuous but overlaps at the equator portion of the tire, allows the resistive element to move to some extent prior to vulcanization due to the overlapping portion of the equator region of the tire, which not only allows the desired reinforcement under the tread, It is described in patent FR 1 425 801 that it improves the balance of forces during shaping of the sulfur tire blank.

This movement is because the contact width between the two overlaps and the overlaps that need to be secured by shearing the two parts is so large that the width is usually about the same as the width of the crown stiffener, so that the intermediate layer is Insufficient to avoid flow through. In addition, the radial overlap of the various carcass layers underneath the crown reinforcement affects the position of the meridian flexibility-crown reinforcement assembly, in particular the intermediate bending axis, of the carcass reinforcement, which is not always desirable.

Accordingly, the present invention provides another solution, which comprises subdividing the continuous carcass reinforcement from one bead wire to another bead wire into three parts, and the elasticity of the portion reinforcing the sidewall of the tire. Providing a portion of elastic carcass reinforcement under the crown reinforcement, wherein the large resilience is obtained by using a cut reinforcement element.

According to the invention, the tire consists of at least one ply of stiffener elements secured to at least one bead wire in each tire bead, the carcass stiffeners intersecting with each other from one ply to the next ply so that 10 A crown reinforcement consisting of two or more acting plies formed of reinforcements forming an angle between ⁰ and 45 ⁰ , comprising a carcass reinforcement which is radially covered, wherein the tire is between 0.4 and 0.4 of the width of the widest acting crown ply. The portion of the carcass reinforcement under the crown reinforcement centered at the equator plane with an axial width of 1 times is formed from the cut reinforcement element.

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A preferred solution is to configure each stiffener element of the portion of the carcass stiffener that is between 0.4 and 1 times the axial width of the widest working crown ply so that it is cut at least once.

Preferably, the area under the crown reinforcement has a linear tensile strength per unit width of 0.1 to 0.7 times greater than each partial linear tensile strength of the same carcass reinforcement that reinforces the sidewalls of the tire, so that the linear strength between The ratio of is between 0.2 and 1 when the tire is vulcanized.

The strength before vulcanization of the portion under the crown, which is less than 0.1 times the strength of the side wall portion, cannot guarantee the geometric stability of the uncured tire blank and, under vulcanization conditions, sufficient tension in satisfactory triangulation of the crown reinforcement Can not provide. Linear strength greater than 0.7 times the strength of the side wall portions is inevitable in the flow phenomenon of the inner rubber layer.

The linear tensile strength arises from the tensile force acting on the strip of carcass reinforcement of unit width, which is necessary to obtain a relative elongation of 0.5%, which is represented by the following equation.

Where R is the linear strength and dF / dε is the deviation of the force proportional to the unit width with respect to the relative elongation ε. In the case of linear strength in unvulcanized conditions, it is measured in the intermediate product, ie strips of unvulcanized carcass reinforcement, and in the case of linear strength in vulcanized conditions in strips having unit widths cut from vulcanized tires.

Whatever solution is chosen to obtain this linear strength ratio, the tensile forces of the reinforcing elements of the carcass reinforcement at the sidewalls of the tire are almost the same around the circumferential direction of the tire. In addition to the fact that the present invention solves the problem of the flow phenomenon of the inner layer on which the present invention is based, the solution of the cut reinforcement element is that the partial carcass reinforcement is a triangular split reinforcement because the cut element provides a specific resistance to the compressive force. Keep your role. This solution is the most reliable and the least expensive in the industry, improves uniformity, and greatly reduces radial variations without having to consider harmonization, thereby increasing comfort or visually perceptible tires. Has a number of advantages that can reduce the deformation of the outer surface of the side wall, which gives a bad appearance.

1 is a schematic view in meridian cross section of a first preferred variant of a tire according to the invention;

2 is a plan view of a carcass reinforcement of the tire of FIG.

3 is a plan view schematically showing a second carcass stiffener variant.

4 is a plan view of a carcass reinforcement formed of two plies according to the present invention.

The tire P shown in FIG. 1 comprises a carcass reinforcement consisting of a single carcass ply 1 formed from a reinforcement element which is a radial polyester cable. The ply 1 is fixed to the bead wire 2 at each tire bead with one part 10 folded back on itself. On either side of the central portion and the equator plane XX ', the carcass ply 1 is, in the case described, on the one hand two action plies 31, 32 formed of non-extensible metal steel parallel to one another in each ply. ) to the configuration and to form a 22 ⁰ angle (α) with respect to the circumferential direction, and mutually crossing from one ply (31) to the next ply 32 in the other hand, with respect to the circumferential direction to +5 ⁰ -5 ⁰ range It consists of a so-called protective ply 33 formed of an aliphatic polyamide cable forming an angle β at. The tire P is composed of several known rubber mixtures commonly used, such as a tread 4 secured to the beads by two side walls 5 and an inner layer, various fillers on and around the fixed bead-wire, and layer protective beads. And so on.

The action ply 31 closest to the carcass ply 1 is the widest in the axial direction and its axial width L ₃₁ is equal to 140 mm. The AB portion of the carcass ply 1 disposed under the crown reinforcement on one side of the equator plane XX 'has an axial width (L ₁₁ ) or width 0.91 times the width (L ₃₁ ) equal to 130 mm. The cable 11 at the AB portion of the carcass ply in the state (FIG. 2) is provided with a width l between the cuts 12 of the adjacent cable equal to 0.4 times the width L ₃₁ or 56 mm in the case described. A cut 12 for a cable with cuts in a zigzag circumferential adjacent cable 11, said cuts being considered to be formed in the center of the space 13 between two sections 110 of the cable. The width l ₁ of the overlap between the cables is a function of the width l ₂ of the space 13 between the ends of the two sections 110 of the cable 11 and, in the case described, equal to 55 mm. This is an unvulcanized bath of strips (AD) of equal length in the carcass ply reinforcing the sidewalls. The strip width AB of the unit width, which does not have to be cut, if the linear strength of the strip AB is equal to 0.6 times the linear strength of, but in unvulcanized conditions is equal to the 0.6 times linear strength of the sidewall strip AD under the same conditions. Linear strength of the unvulcanized condition for.

Although the line CC of the cutout is axially separated by an amount equal to 0.4 times the width L ₃₁ , as shown in FIG. 2, the spacing between the lines CC is within the scope of the present invention. It is certain that the width L ₃₁ may be between 0.28 and 0.7 times.

The AB portion of the carcass ply 1 shown in FIG. 3 is different from the portion of FIG. 2 in the construction of the cutout 12. In practice, one cable 11 of each of the two cable pairs has two cuts 12 and the distance l is equal to 0.4 times the width L ₃₁ and one of the cuts 12 is circumferentially. One of the two adjacent cables 11 is in the circumferential extension of one of the cuts 12, while the other is in the circumferential extension of the cut 12 of the other cable 11 adjacent in the circumferential direction. . The lines CC thus formed are separated by a distance l. This configuration makes it easier to control the cutting process of the reinforcing cable, while ensuring that the number of cuts is sufficient.

FIG. 4 shows the configuration of the cutout 12 in the cable 11 forming two carcass stiffener plies 1 for the radial tire, the lines of the cutout being 0.2 times, as clearly shown in FIG. 4. It is separated by a distance equal to the width (L ₃₁ ) of. As shown, the length of the overlap between the cables of one ply is preferably equal to the length of the overlap between the cables of the other plies.

The carcass reinforcement with the cable cut at the AB site is usually prepared by assembling the cable, coating it with a rubber mixture and then cutting to obtain the desired meridian length. The prepared ply and the cut in this manner are placed on a table, in which the device with several cutting blades moves vertically and moves downward to cut the cable, the cutting blade being cut so that the cut is made at the desired position. Pre-adjusted in lateral and transverse spacing.

Claims (5)

Consists of at least one ply 1 of stiffener elements 11 fixed to at least one bead wire 2 in each tire bead, the carcass reinforcement being radially covered by a crown stiffener 3, The crown stiffener 3 consists of two or more acting crown plies 31, 32 formed of stiffener elements which cross each other from one ply to the next ply and form an angle between 10 ⁰ and 45 ⁰ with respect to the circumferential direction. In the tire, The carcass reinforcement disposed below the crown reinforcement 3 centered at the equator plane XX 'and having an axial width L ₁₁ of 0.4 to 1 times the width L31 of the widest working crown ply 31. The AB portion of (1) is formed of a cut reinforcement element (11). 2. Tire according to claim 1, wherein each stiffener element (11) at the AB portion of the carcass stiffener (1) is cut at least once. 2. The AB portion of the carcass stiffener (1) according to claim 1 is 0.1 to 0.7 than the linear tensile strength of each portion (AD) of the same carcass stiffener (1) reinforcing the sidewall (5) of the tire (P). A tire having a linear tensile strength per unit width of twice in unvulcanized conditions, so that the ratio between the linear strengths is between 0.2 and 1 when the tire P is vulcanized. 2. The width L ₃₁ of the widest working crown ply 31 according to claim 1, wherein the cuts 12 between the sections 110 are zigzag between two circumferentially adjacent stiffener elements 11. A tire, characterized in that for forming a line (CC) of the cuts axially separated by an amount (L) between 0.28 and 0.7 times. 2. A stiffener element (11) according to claim 1, wherein one of the two circumferentially adjacent pairs of stiffener elements (11) has two cuts (12) and one of the two cuts (12) is adjacent in two circumferential directions. One of the stiffener elements 11 is in the circumferential extension of one cut 12, and the other cut 12 is in the circumferential extension of the cut 12 in a circumferentially adjacent stiffener element 11. And the lines (CC) of the cuts so formed are axially separated by an amount (L) between 0.28 and 0.7 times the width (L ₃₁ ) of the widest working crown ply (31).

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